KR20130079392A - Antenna assembly and antenna design having an improved signal-to-noise ratio - Google Patents

Abstract

The present invention relates to an antenna assembly, the antenna assembly comprising: at least one electrically insulating substrate; At least one conductive coating, covering at least the surface of the substrate in a section-wise manner and functioning as a planar antenna for receiving electromagnetic waves at least in a section-wise manner; At least one first coupling electrode electrically coupled to the conductive coating to extract an effective signal from the planar antenna; At least one interference source arranged to allow interference signals to be received by the planar antenna; Conductive structures serving as ground; And at least one second coupling electrode electrically coupled to the conductive coating to couple out interfering signals received by the planar antenna from the planar antenna. At least one second coupling electrode has a first coupling surface, the conductive structure has a second coupling surface capacitively coupled to the first coupling surface, and the two coupling surfaces are from a planar antenna. And selectively allow passage of a frequency range corresponding to the extracted interference signals.

Description

ANTENNA ASSEMBLY AND ANTENNA DESIGN HAVING AN IMPROVED SIGNAL-TO-NOISE RATIO

The present invention relates to an antenna assembly and antenna structure having a planar antenna for receiving electromagnetic waves, and a method for operating the antenna assembly.

Substrates with conductive coatings are already frequently described in the patent literature. By way of example only, reference is made to DE 19858227 C1, DE # 10200705286, DE 102008018147 A1, and DE 102008029986 A1 in this regard. In general, conductive coatings function to reflect heat rays and thus provide improved thermal comfort, for example, in a vehicle or building. Frequently, conductive coatings are also used as heating layers for heating the entire surface of a transparent pane.

As known from the publications of DE 10106125 A1, DE # 10319606 A1, EP # 0720249 A2, US # 2003/0112190 A1, and DE 19843338 C2, due to the conductivity, transparent coatings are also planar antennas for receiving electromagnetic waves. It can also be used as. To this end, the conductive coating is galvanically coupled or capacitively coupled to the coupling electrode and the antenna signal can be used in the edge region of the plate member. By convention, the antenna signal is fed to the antenna amplifier, which antenna amplifier is in particular connected to the vehicle's conductive body, where the body has an effective reference potential for high frequency applications predetermined for the antenna signal by this electrical connection. The difference between the reference potential and the potential of the antenna signal produces available antenna power.

Now, due to the large antenna surface, electromagnetic signals can be received by planar antennas within a relatively large area. As a result, in a vehicle, for example, undesirable interference signals from electronic devices such as cameras, sensors, instrument clusters, engine control devices, as well as valid signals can be received by the planar antenna. The signal-to-noise ratio (SNR) of the planar antenna can be significantly worsened due to these interfering signals.

A general approach to improving the signal to noise ratio includes preventing interfering signals by suppressing and shielding the source of interference. Also, if a relatively large geometrical distance is maintained between the interferers and the planar antenna, the influence of the interfering signals can be reduced. In practice, however, it is most difficult to realize these requirements. On the other hand, suppression and shielding of interference sources are technically complex and are associated with relatively high costs. On the other hand, a reasonably long distance between the interference source and the planar antenna is often not maintained, for example in the case of a front-mounted engine and a planar antenna attached to the windshield. This situation is further complicated by the fact that the electrical devices of modern vehicles are often provided adjacent to the foot portion of the indoor rearview mirror, and such electrical devices can act as an interference source for the planar antenna on the windshield. The practical solution can be selectively obtained only by attaching the planar antenna to the back glass.

In contrast, it is an object of the present invention to further provide conventional antenna assemblies with planar antennas such that despite the presence of an interference source emitting interference signals to the planar antenna, effective signals can be received with a satisfactory signal-to-noise ratio. To improve. Furthermore, such antenna assemblies must be cost effective, simple, and reliably and securely function in series production. These and other objects are achieved by an antenna assembly (system), antenna structure, and method of operating the antenna assembly having the features of the independent claims. Preferred embodiments of the invention are described through the features of the dependent claims.

The antenna assembly of the present invention comprises at least one electrically insulating, preferably transparent, substrate and preferably at least one conductive coating, wherein the conductive coating is at least section-wise (at least one section). Thereby covering at least one surface of the substrate and acting as a plane-shaped antenna (planar antenna) for receiving electromagnetic waves at least in a section-wise manner (at least one section). The conductive coating can be suitably configured for use as a planar antenna, for which it can cover most of the substrate. The antenna assembly may include, for example, a single plate member or a stacked plate member. In general, the laminated plate preferably comprises two transparent first substrates, the first substrates being conductive on at least one surface of the first substrate of at least one of the two first substrates of the laminated plate member. With the coating in place, it corresponds to the inner plate member and the outer plate member which are fixedly bonded to each other by at least one thermoplastic adhesive layer. In addition, the laminated plate may have another second substrate positioned between the two first substrates and different from the first substrate. In addition or alternatively to the first substrate, the second substrate may serve as a carrier for the conductive coating, wherein at least one surface of the second substrate may have a conductive coating.

The antenna assembly according to the present invention further comprises at least one first coupling electrode electrically coupled to the conductive coating to extract out effective signals from the planar antenna. The first coupling electrode can be capacitively coupled or electrically coupled to the conductive coating, for example.

The antenna assembly further comprises at least one interference source, the interference source being electromagnetically interfered by a planar antenna as well as a conductive structure acting as a ground, for example a metal window frame or metal body of a vehicle. It is arranged to be received. The antenna assembly according to the invention comprises at least one electrically coupled to a conductive coating to capacitive extract (coup out) interference signals of at least one external interference source received by the planar antenna. It further includes a second coupling electrode. The second coupling electrode can be capacitively or electrically coupled to the conductive coating. The antenna assembly according to the invention thus serves in particular to extract (coup out) the interference signals from the planar antenna, which signals are received by the planar antenna as electromagnetic waves, that is to say that the interference signals are separate It is received by a planar antenna that functions as an antenna, rather than being transferred into the planar antenna via electrical or capacitive coupling via electrical components (capacitors).

According to the invention, at least one second coupling electrode is capacitively coupled to a conductive structure acting as electrical ground, wherein the second coupling electrode has a first coupling surface, the conductive structure being the first coupling surface. It has a second coupling surface (coupling counter surface) which is capacitively coupled to one coupling surface. The capacitive coupling surfaces of the at least one second coupling electrode and of the conductive structure serving as electrical ground are suitably configured for capacitive coupling, that is, they are disposed opposite each other with an appropriate distance therebetween. .

Capacitively coupled coupling surfaces are configured to allow passage of a pre-definable frequency range, which frequency range preferably corresponds to the frequency range of the interference signals to be extracted (coupled out) from the planar antenna, In other words, capacitive coupling surfaces do not allow passage of frequencies other than their frequency range. In particular, capacitive coupling surfaces have a threshold frequency or pass of 170 MHz, corresponding to the frequency range of terrestrial broadcast bands III-V, which can be well received by a linear antenna. passthrough) Optionally allows passage of a frequency range above the frequency. The desired frequency selectivity can be adjusted in a simple manner through the distance and magnitude between the capacitively coupled coupling surfaces, that is to say to allow for the passage of the frequency range of interfering signals of the interfering source (s). The distance and size between the enemy coupling surfaces is realized.

In a particularly preferred embodiment of the antenna assembly according to the invention, at least one second coupling electrode is embodied in the form of a projecting (flat) edge section of the conductive coating, wherein the projecting edge section acts as ground. It is implemented to be capacitively coupled opposite the second coupling surface of the conductive structure. By this means, a simple and cost effective realization of the antenna assembly according to the invention in the series production is especially possible, since at least one second coupling electrode can be produced as a section of the conductive coating. However, it may also be considered to produce a second coupling electrode, for example from a metal foil strip that is electrically or capacitively coupled to the conductive coating.

In the antenna assembly according to the invention, it is preferable to extract (coup out) the interference signals from the planar antenna arranged near the first coupling electrode such that at least one second coupling electrode extracts valid signals from the planar antenna. . In general, antenna signals are extracted at different coupling electrodes depending on the potential difference and distance from the surface section of the conductive coating serving as a planar antenna; The greater the potential difference between the coupling electrode and the surface section of the conductive coating, and the shorter the distance to this section, the more the signal is extracted by the coupling electrode (and less by the other "competitive" coupling electrode). ). In the antenna assembly according to the invention, by means of the spatially close arrangement of the first coupling electrode and the at least one second coupling electrode, it is advantageously achieved that the potential differences generated upon signal reception are substantially the same at both coupling electrodes. Can be. Through the frequency-selective pass behavior of the at least one second coupling electrode, the interference signals are extracted (coupled out) through the second coupling electrode and the valid signals are extracted (coupled) through the first coupling electrode Out) can additionally be achieved. By means of the spatial proximity arrangement of the first coupling electrode and the at least one second coupling electrode, the interference signals of all the interference sources acting on the planar antenna and also above the pass frequency or threshold frequency of the second coupling electrode are derived from the planar antenna. Reliable and safe extraction can also be achieved. Thus, the signal-to-noise ratio of the planar antenna can be significantly improved. The term "proximity" is understood to mean the arrangement of the first coupling electrode and the at least one second coupling electrode when the coupling electrodes cause the aforementioned desired effect. In particular, the at least one second coupling electrode can for this purpose have a distance from the first coupling electrode of less than one quarter of the minimum wavelength of the interference signals extracted from the planar antenna. By this means, the signal-to-noise ratio of the planar antenna can be particularly well improved.

In another preferred embodiment of the antenna assembly according to the invention, a second coupling electrode is disposed between the region region of the conductive coating (hereinafter referred to as "interference region region member") and the first coupling electrode, the conductive coating The points of the region region of are generally distinguished in that they have a very short distance from the physically implemented interference source. The points of the interference zone zone source can in particular have an extremely short vertical distance from the interference source. The interference zone zone member may be a projection zone resulting from, for example, projection onto a conductive coating, in particular from orthogonal parallel projection. In general, a physical interference source can be perceived in the projection as a flat, extensive body. By means of a second coupling electrode disposed between the interference region zone source and the first coupling electrode, the spatially selective extraction (coupling out) of the interference signals from the planar antenna does not substantially impair the reception of valid signals. Without, it may be advantageous. Due to the distance condition between the interfering source and the interfering region zone source, the interfering signals of the interfering source are received within the interfering region zone source with an extremely large signal amplitude or signal strength. The potential differences between the second coupling electrode and the surface section of the conductive coating and which occur upon receipt of the interference signals are greater than the potential differences between the first coupling electrode and this surface section, so that the interference signals are applied to the second coupling electrode. Mainly by extraction. The shape of the interference area zone member generally depends on the shape of the interference source. Furthermore, by the spatial position of the second coupling electrode between the interference region zone member and the first coupling electrode, the desired extraction of the interference signals through the second coupling electrode can be achieved. The first coupling electrode can additionally retain valid signals from the flat sections of the planar antenna, which valid signals are mainly extracted by the first coupling electrode. Thus, the signal-to-noise ratio of the planar antenna can be significantly improved. In the case of at least one second coupling electrode, it may be desirable to have a distance from the interference area zone source that is less than one quarter of the minimum wavelength of the interference signals, as a result of which further improvement of the signal-to-noise ratio of the planar antenna This can be obtained.

In another preferred embodiment of the antenna assembly according to the invention, at least one second coupling electrode is arranged near the interference zone zone member of the conductive coating, the points of which zone circle being as short as possible from the at least one interference source. And thus an extremely large signal amplitude relative to the interfering signals of the interfering source. By means of the second coupling electrode, spatially selective extraction of interfering signals from the planar antenna can preferably be made without substantially impairing the reception of valid signals. Proximity placement of the second coupling electrode relative to the interfering region zone source results in potential differences between the second coupling electrode and the surface section of the planar antenna containing the interfering region zone source upon receipt of the interference signals of the interfering source, Such potential differences are greater than the potential difference between this surface section and the first coupling electrode, whereby the interference signals are mainly extracted by the second coupling electrode. The first coupling electrode can further retain valid signals from the flat sections of the planar antenna, with potential differences greater than the potential difference between the first coupling electrode and the surface section comprising the interference region zone source. Thus, the signal-to-noise ratio of the planar antenna can be significantly improved. In the case of at least one second coupling electrode, it is preferred to have a distance from the interference area zone source which is less than one quarter of the minimum wavelength of the interference signals, by which means the signal to noise ratio of the planar antenna can be further improved. have.

In another preferred embodiment of the antenna assembly, the first coupling electrode is electrically coupled to an unshielded linear conductor, hereinafter referred to as an "antenna conductor". The antenna conductor functions as a linear antenna for receiving electromagnetic waves. In this case, the linear conductor is located outside of the area that can be projected by orthogonal parallel projection onto the planar antenna, which serves as the projection area, whereby the antenna foot point of the linear antenna and the linear antenna and It becomes the common antenna foot point of the planar antenna. The first coupling electrode can, for example, be capacitively or electrically coupled to the linear antenna conductor. In this embodiment, the antenna assembly thus has a hybrid structure made of a planar antenna and a linear antenna.

The antenna conductor functions as a linear antenna and is configured appropriately for this purpose, that is to say has a form suitable for reception in the desired frequency range. In contrast to and in contrast to planar emitters, linear antennas or linear emitters have a geometric length L that is many times larger than the geometric width B. The geometric length of the linear emitter is the distance between the antenna foot point and the antenna tip; The geometric width is the dimension perpendicular to it. As a result, in the case of linear emitters, the following relation applies: L / B ≥ 100 is applied. In the case of their geometric height H, in general, the corresponding relation L / H ≥ 100 is applied, wherein the "geometric height H" is perpendicular to the length L and also to the width B Means one dimension. The satisfactory antenna signal may be provided by linear emitters in the range of terrestrial broadcast bands II to V. In accordance with the provisions of the International Telecommunication Union (ITU), these bands range from 87.5 MHz to 862 MHz (Band II: 87.5-108 MHz, Band III: 174-230 MHz, Band IV: 470-606 MHz, Band V : 606-862 MHz). However, satisfactory reception performance cannot be obtained in the leading frequency range of band I (47-68 MHz). This applies likewise for frequencies below band I.

In a hybrid antenna assembly, it is essential that the antenna conductors are located outside of the area formed by the projection operation, which can be projected by orthogonal parallel projection onto a planar antenna or conductive coating where each point of the area functions as a projection area. It is defined that there is. If the conductive coating is activated as a planar antenna only in a section-wise manner, only a portion of the conductive coating that is activated as a planar antenna functions as a projection area. Thus, the antenna conductor is not located within the area defined by the projection area. As is common, in parallel projection, the projection beams collide with the projection area parallel and perpendicular to each other, which projection area is in this case a conductive coating which functions as a planar antenna or as part activated as a planar antenna. The projection center is infinity. In flat substrates and thus flat conductive coatings, the projection area is the projection plane that contains the coating. The area is bounded by a (virtual) edge surface, located on the peripheral edge of the conductive coating or on the peripheral edge of the portion of the conductive coating that is activated as a planar antenna and perpendicular to the projection area.

In a hybrid antenna assembly, the antenna foot point of the linear antenna becomes the common antenna foot point of the linear antenna and the planar antenna. As is general, the term "antenna foot point" refers to an electrical contact for picking up received antenna signals, and in particular, reference to a reference potential (e.g., ground) for determining the signal level of the antenna signals. reference) is made on such a contact. Accordingly, the hybrid antenna assembly is preferably good in large bandwidth, combining the preferred reception features of planar emitters in frequency band ranges I and II with the preferred reception features of planar emitters in frequency band ranges II to V. Enable reception. By means of the placement of linear emitters outside of the areas that can be projected onto the planar antenna by orthogonal parallel projection, the electrical load of the linear emitters by the planar emitters can be particularly preferably avoided. Thus, for example, in the case of a windshield functioning as an antenna plate member, the hybrid antenna assembly allows the entire frequency band range I to V to be used with satisfactory reception performance.

In a hybrid antenna assembly, the antenna conductor may be specifically configured for the reception of the range of local broadcast bands III-V, and for this purpose, preferably a relation of length / width ≥ 100 or L / H ≥ 100 Corresponding to, it may have a length greater than 100 millimeters (mm) and a width less than 1 mm and a height less than 1 mm. For this purpose, it would be more desirable for the antenna conductor to have a distribution resistance of less than 20 ohms / m, particularly preferably 10 ohms / m. In addition, in the hybrid antenna assembly, the first coupling electrode can be electrically coupled to the conductive coating, whereby the reception performance (signal level) of the planar antenna is as high as possible. Such means preferably enables signal level optimization of the planar antenna for improving the reception characteristics of the hybrid antenna assembly. In addition, in the hybrid antenna assembly, the common antenna foot points of the planar antenna and the linear antenna can be electrically connected to an electronic signal processing device, for example an antenna amplifier, for processing of antenna signals received via the connector conductor, wherein the connector The connector conductors are arranged so that the length of the conductors is as short as possible. Such means can advantageously eliminate the need for the use of special high frequency conductors for connector conductors with signal conductors and at least one incidental ground conductor, and because of the short signal transmission path It allows the use of more economical signal conductors, such as wire or strip-shaped flat contours, which can also be connected using relatively less complex connection techniques, in particular not provided for high frequency transmission. This allows for significant cost savings in the production of hybrid antenna assemblies. In addition, in the hybrid antenna assembly, the conductive coating can cover the surface of the substrate except for the electrically insulating edge strips around, and the antenna conductors can be projected by orthogonal parallel projection onto the edge strips serving as the projection area. It is located inside of the area. To this end, an antenna conductor can be applied, for example, on a substrate in the area of the edge strip. Such means enable particularly simple manufacture of the hybrid antenna assembly. If the hybrid antenna assembly is implemented in the form of a stacked plate member, the conductive coating can be located on one surface of at least one substrate and the linear antenna conductors are on another surface of the same substrate or on a surface of a different substrate. It can be located at. By this means, particularly simple production of the hybrid antenna assembly according to the invention can be realized. In addition, in a hybrid antenna assembly, the first coupling electrode and the antenna conductor may be conductively connected to each other, thereby providing a design possibility of the first coupling electrode, which is particularly independent of the electrical connection to the linear antenna conductor, This can improve the performance of the hybrid antenna assembly. In addition, in a hybrid antenna assembly, an antenna conductor may be located on one surface of at least one substrate, and a common antenna foot point may be located on another surface of the same substrate or on a surface of a different substrate. Can be. To this end, the antenna conductor and the common antenna foot point are conductively connected to each other via a second connecting conductor. By this means, in particular, the electrical connection of the common antenna foot point to the downstream antenna electronics can be realized particularly simply. In addition, in a hybrid antenna assembly, a linear antenna conductor made of a metal printing paste can be printed or laid in the form of a wire on at least one substrate, for example using a screen printing method, whereby the antenna Particularly simple production of conductors is possible. Further, in the hybrid antenna assembly, at least one conductors selected between the first coupling electrode, the first connecting conductor, and the second connecting conductor can lead to the edge of the at least one substrate and taper in the area of the edge. It can be implemented as a flat conductor having a width. In this way, a reduced coupling surface can preferably be obtained on the substrate edge, for example in order to reduce capacitive coupling with the conductive vehicle body when the conductor is drawn out of the laminated plate member. In addition, in the hybrid antenna assembly, the linear antenna and the first coupling electrode as well as the two connecting conductors (if present) can be masked by an opaque masking layer, thereby improving the visible appearance of the antenna assembly. Can be. In addition, in a hybrid antenna assembly, the conductive coating can include at least two planar pieces that are electrically insulated from each other by at least one linear, electrically insulated zone. In addition, at least one planar piece is divided by linear electrically insulating regions. In particular, it would be particularly desirable if the peripheral edge region of the conductive coating had a plurality of planar segments divided by linear electrically insulating regions. Reference may be made to international patent application PCT / EP2009 / 066237, which is not published in connection with fragmentation of such conductive coatings, the disclosure of which is incorporated herein by reference.

In a particularly preferred manner, in a hybrid antenna assembly, interference signals that lie in a frequency range that can be well received by a linear antenna, ie interference signals in the frequency range of the local broadcast bands III-V above 170 MHz Can be extracted from. Thus, no loss occurs in the effective signal portion of the planar antenna. Thus, the second coupling electrode preferably has a high pass range corresponding to the frequency range of the local broadcast bands III-V, in particular corresponding to the frequency range of the local broadcast bands IV and V.

The invention further extends to an antenna structure, which antenna structure comprises at least one electrically insulating, in particular transparent substrate; At least one conductive coating, particularly transparent, covering at least a section-wise (at least the section) the surface of the substrate and serving as a planar antenna for receiving electromagnetic waves at least in the section-wise (at least the section); At least one first coupling electrode coupled to a conductive coating to extract (couple out) an effective signal from the planar antenna; Having at least one second coupling electrode electrically coupled to the conductive coating to extract (couple out) at least one interference signal from the planar antenna; The at least one second coupling electrode has a first coupling surface configured to be capacitively coupled to a second coupling surface of the conductive structure acting as electrical ground, the first coupling surface having a second coupling Together with the ring surface, it is configured to selectively allow passage of a frequency range corresponding to interference signals extracted (coupled out) from the planar antenna.

In a preferred embodiment of the antenna structure according to the invention, at least one second coupling electrode is configured in the form of a protruding edge section of the conductive coating.

The present invention, as described above, in a land, air, or sea vehicle, in particular in a vehicle, for example as a windshield, rear glass, side glass, and / or glass ceiling, as well as furniture, devices , And as an embedded part in buildings, and as separate pieces for functional and / or decorative purposes, further extends to the use of antenna structures.

The invention further extends to a method of operating such an antenna assembly, in which the effective signals are extracted (coupled out) from the planar antenna via the first coupling electrode and the interfering signals are planarized through the second coupling electrode. It is selectively extracted (coupled out) from the antenna.

Such a method includes the following steps:

Receiving effective signals by a planar antenna implemented in the form of a particularly transparent conductive coating applied to at least one electrically insulating, in particular transparent substrate;

Extracting (coupling out) valid signals from the planar antenna by a first coupling electrode electrically coupled to the coating;

Selectively extracting (coupling out) interfering signals from the planar antenna of at least one interfering source (electromagnetically) received by the planar antenna by a second coupling electrode electrically coupled to a coating; Including,

The second coupling electrode is capacitively coupled to a conductive structure, for example a metal vehicle body or a metal window frame, which serves as ground, the second coupling electrode having a first coupling surface, the conductive structure being the first It has a second coupling surface (coupling counter surface) capacitively coupled to the coupling surface.

In a preferred embodiment of the method according to the invention, the interference signals received by the planar antenna are extracted (coupled out) from the planar antenna via at least one second coupling electrode configured in the form of a projecting edge section of the conductive coating. .

The method according to the invention can, in particular, be realized in the above-described antenna assembly according to the invention.

The various embodiments of the antenna structure or of the antenna assembly as well as the method for the operation of the antenna assembly according to the invention can be realized individually or in any combination, in order to achieve further improvement of the signal to noise ratio of the antenna assembly. I can understand that. In particular, the foregoing features and features described below can be used in the combinations described, as well as in other combinations or alone, without departing from the scope of the present invention.

In the following, with reference to the accompanying drawings, the present invention will be described in detail based on an exemplary embodiment. The drawings show a simplified representation rather than a scale.
1 is a schematic perspective view of a hybrid antenna assembly according to a first exemplary embodiment of the present invention implemented in the form of a laminated plate member.
2A-2D are of FIG. 1 along section line AA (FIG. 2A), section line BB (FIG. 2B), section line A′-A ′ (FIG. 2C), and section line B′-B ′ (FIG. 2D). Cross-sectional views of a hybrid antenna assembly.
3A and 3B are cross-sectional views of a first variant of the hybrid antenna assembly of FIG. 1 along section line AA (FIG. 3A) and section line BB (FIG. 3B).
4A and 4B are cross-sectional views of a second variant of the hybrid antenna assembly of FIG. 1 along section line AA (FIG. 4A) and section line BB (FIG. 4B).
5A and 5B are cross-sectional views of a third variant of the hybrid antenna assembly of FIG. 1 along section line AA (FIG. 5A) and section line BB (FIG. 5B).
6 are cross-sectional views of a fourth variant of the hybrid antenna assembly of FIG. 1 along section line BB.
7 is a schematic perspective view of a hybrid antenna assembly according to a second exemplary embodiment of the present invention implemented in the form of a laminated plate member.
8A and 8B are cross-sectional views of the hybrid antenna assembly of FIG. 7 along section line AA (FIG. 8A) and section line BB (FIG. 8B).
9 is a cross-sectional view of a variant of the hybrid antenna assembly of FIG. 7 along section line AA.

Referring first to FIGS. 1 and 2A-2D, a hybrid antenna structure, generally designated as 1, and an antenna assembly 100 comprising such antenna structure 1 are shown as a first exemplary embodiment of the invention. . In this case, the hybrid antenna structure 1 is embodied, for example, as a transparent laminated plate member 20, only partially shown in FIG. 1. The laminated plate member 20 is, for example, transparent to visible light in the wavelength range of 350 nm to 800 nm, wherein the term “transparent” is greater than 50%, preferably greater than 75%, and particularly preferably Light transmission of greater than 80%. The laminated plate member 20, for example, functions as a windshield of the vehicle, but may be used differently.

The laminated plate member 20 comprises two transparent individual plate members, ie a rigid outer plate member 2 and a rigid inner plate member 3, which are fixedly bonded to each other by a transparent thermoplastic adhesive layer 21. The individual plate members have approximately the same size and can be made, for example, of glass, in particular float glass, cast glass, and ceramic glass, likewise non-glass materials, eg For example, plastics, in particular polystyrene (PS), polyamide (PA), polyester (PE), polyvinyl chloride (PVC), polycarbonate (PC), polymethyl methacrylate (PMA), or polyethylene terephthalate ( PET). In general, any material with sufficient transparency, adequate chemical resistance, and adequate shape and size stability can be used. For example, the outer plate member 2 and the inner plate member 3 may be made of a flexible material for other uses such as decorative pieces. The thickness of each of the outer plate member 2 and the inner plate member 3 can vary greatly depending on the application and in the case of glass, for example, can range from 1 to 24 mm.

The laminated plate member 20 has at least approximately a trapezoidal curved contour (FIG. 1 is only partially discernible), and the contour is a common edge of the plate member made of two separate plate members 2, 3. Resulting from (5), the edge 5 of the plate member consists of two opposing long edges 5a of the plate member and two opposing short edges 5b of the plate member. In a conventional manner, the surfaces of the plate members are indicated by the Roman numerals I-IV, and the " side I " corresponds to the first plate member surface 24 of the outer plate member 2; "Side II" corresponds to the second plate member surface 25 of the outer plate member 2; "Side III" corresponds to the third plate member surface 26 of the inner plate member 3; And "side IV" corresponds to the fourth plate member surface 27 of the inner plate member 3. In applications such as windshields, side I faces the outside environment and side IV faces the passenger compartment of the vehicle.

The adhesive layer 21 for bonding the outer plate member 2 and the inner plate member 3 is preferably based on polyvinyl butyral (PVB), ethylene vinyl acetate (EVA), polyurethane (PU). It is preferably made of adhesive plastic. In this case, the adhesive layer 21 is embodied, for example, as a bilayer in the form of two PVB films bonded together (not specifically shown in the figures).

An extensive carrier 4 is located between the outer plate member 2 and the inner plate member 3, which carrier is preferably polyamide (PA), polyurethane (PU), polyvinyl chloride (PVC). ), Preferably based on polycarbonate (PC), polyester (PE), and polyvinyl butyral (PVB), particularly preferably on polyester (PE) and polyethylene terephthalate (PET) do. In this case, the carrier 4 is embodied, for example, in the form of a PET film. The carrier 4 is embedded between the two PVB films of the adhesive layer 21 and between the outer plate member 2 and the inner plate member 3 approximately in the center parallel to the outer plate member and the inner plate member. The first carrier surface 22 faces the second plate member surface 25 and the second carrier surface 23 faces the third plate member surface 26. The carrier 4 does not extend all the way to the edge 5 of the plate member, the carrier edge 29 is set back against the edge 5 of the plate member, and the carrier of the laminated plate member 20 A carrier-free circumferential edge zone 28 is maintained on all sides. For example, in order to reduce capacitive coupling with a conductive vehicle body, which is generally made of sheet metal, the edge zone 28 functions in particular as an electrical insulation of the outwardly conductive coating 6. In addition, the conductive coating 6 is protected against penetration of moisture from the edge of the plate member 5.

The second carrier surface 23 is coated with a transparent, conductive coating 6, which is bounded at all sides by the peripheral coating edge 8. The conductive coating 6 comprises more than 50%, preferably more than 70%, particularly preferably more than 80% and more preferably more than 90% of the second plate member surface 25 or the third plate member surface 26. To cover. The area covered by the conductive coating 6 preferably corresponds to more than 1 m ² , and in general, although the laminated plate member 20 is used as the windshield, for example 100 cm ² to 25 m ² It can be a range. The transparent, conductive coating 6 comprises or consists of at least one conductive material. Examples of these are high conductivity metals such as silver, copper, gold, aluminum or metal alloys such as silver alloyed with molybdenum, palladium, and transparent, conductive oxides (TCOs = transparent conductive oxides). Preferred TCOs are indium tin oxide, fluoride-doped tin dioxide, aluminum-doped tin dioxide, gallium-doped tin dioxide, boron-doped tin dioxide, tin zinc oxide, or antimony-doped tin oxide.

The conductive coating 6 may consist of one individual layer with such conductive material, or a series of layers comprising at least one such individual layer. For example, the series of layers can include at least one layer made of a conductive material and at least one layer made of a dielectric material. The thickness of the conductive coating 6 can vary greatly depending on the application and at any location the thickness ranges from 30 nm to 100 μm. In the case of TCOs, the thickness is preferably in the range from 100 nm to 1.5 μm, more preferably in the range from 150 nm to 1 μm, particularly preferably in the range from 200 nm to 500 nm. When the conductive coating consists of a series of layers having at least one layer made of a conductive material and at least one layer made of a dielectric material, the thickness is preferably in the range of 20 nm to 100 μm, more preferably 25 nm to 90 In the μm range, and particularly preferably in the range from 30 nm to 80 μm. The series of layers preferably has a large thermal stability, and thus a series of layers which are able to withstand without damage, at temperatures above the usual 600 ° C. required for the bending of pane glasses, but also have a low thermal stability Can be provided. The sheet resistance of the conductive coating 6 is preferably less than 20 ohms, for example in the range of 0.5 to 20 ohms. In the exemplary embodiment shown, the exemplary resistance of the conductive coating 6 is, for example, 4 ohms.

The conductive coating 6 is preferably deposited from the gas phase, and for such deposition, known methods such as chemical vapor deposition (CVD) or physical vapor deposition (PVD) can be used. Preferably, the coating 6 is applied by sputtering (magnetron cathode sputtering).

In the laminated plate member 20, the conductive coating 6 preferably functions as a planar antenna for the reception of electromagnetic waves in the frequency range of the local broadcast bands I and II. For this purpose, the conductive coating 6 is electrically coupled to the first coupling electrode 10, in which case such coupling is embodied, for example, as a strip-shaped flat conductor. In an exemplary embodiment, the first coupling electrode 10 is electrically coupled to the conductive coating 6, whereby provision of capacitive coupling is equally possible. The strip-shaped first coupling electrode 10 is made of, for example, a metallic material, preferably silver, and printed, for example, by screen printing. Preferably, such electrodes have a length of more than 10 mm and a width of at least 5 mm, more preferably a length of more than 25 mm and a width of at least 5 mm. In an exemplary embodiment, the first coupling electrode 10 has a length of 300 mm and a width of 5 mm. The thickness of the first coupling electrode 10 is preferably less than 0.015 mm. The specific conductivity of the first coupling electrode 10 made of silver is, for example, 61.35 · 10 ⁶ / ohm · m.

As shown in FIG. 1, the first coupling electrode 10 extends on the conductive coating 6 approximately parallel with the top coating edge 8 and is in direct electrical contact with the conductive coating, and the carrier-free edge Extend into zone 28. In this case, the first coupling electrode 10 is arranged so that the antenna signals of the planar antenna are optimized with respect to the reception performance (signal level).

As shown in FIGS. 2A and 2B, the conductive coating 6 comprises a plurality of electrically insulating fragments, within the strip-shaped edge area 15 adjacent the carrier edge 29, for example by laser machining. Divided into sections 16, between such fragments, in each case, electrically insulating (striped) regions 17 are located. The edge area 15 extends substantially parallel to the carrier edge 29 and can in particular follow the circumference on all sides. By this means, capacitive coupling to the peripheral conductive structures of the conductive coating 6, for example to the conductive vehicle body, is prevented. Since the edge region 15 of the conductive coating 6 does not operate as a planar antenna, the portion of the conductive coating 6 that operates to function as a planar antenna is bounded by the coating edge 8 '.

Within the carrier-free edge zone 28 of the laminated plate member 20, embedded in the adhesive layer 4, a linear unshielded antenna conductor 12 is located, which conductor is preferably local In the frequency range of the broadcast bands II to V, particularly preferably in the frequency range of the local broadcast bands III to V, it functions as a linear antenna for the reception of electromagnetic waves and is suitably configured for this. In this exemplary embodiment, the antenna conductor 12 is preferably implemented in the form of a wire 18 longer than 100 mm and narrower than 1 mm. The distributed resistance of the antenna conductor 12 is preferably less than 20 ohm / m, particularly preferably less than 10 ohm / m. In the described embodiment, the antenna conductor 12 is about 650 mm long and 0.75 mm wide. The distribution resistance is 5 ohm / m, for example.

The antenna conductor 12, in this case, has at least an approximate straight-line path, for example, and is located completely within the carrier-free and coating-free edge zone 28 of the laminated plate member 20. For example, under a vehicle lining (not shown) in the region of the masking strip 9, it extends mainly along the short edge 5b of the plate member. The antenna conductor 12 has a suitable distance from both the edge 5 and the coating edge 8 of the plate member, whereby capacitive coupling to the conductive coating 6 and the vehicle body is prevented. In particular, the enlargement of the distance between the conductive coating 6 and the linear antenna effective for high frequency is preferably achieved by the segmented edge area 15.

All points contained therein can be imaged by orthogonal parallel projection onto a conductive coating 6 (or part of a conductive coating 6 acting as a planar antenna) that serves as a planar antenna and represents a projection area. Since the antenna conductor 12 is located outside of the region 30 shown schematically in FIG. 2A, which is defined, the linear antenna is not electrically affected by the planar antenna. This area 30 defined by the projection operation is bounded by a virtual boundary surface 32, which is disposed on the coating edge 8 or 8 ′ and perpendicular to the carrier 21. Sorted by. In the case of the segmented edge region 15, the boundary surface 32 is disposed on the coating edge 8 ′ because the antenna function of the conductive coating 6 is important for the positioning of the antenna conductor.

The first coupling electrode 10 is electrically coupled to the linear antenna conductor 12 on the first conductor contact 11 (not specifically shown). In this exemplary embodiment, the first coupling electrode 10 is electrically coupled to the antenna conductor 12, whereby provision of capacitive coupling is equally possible. The first connector contact 11 of the first coupling electrode 10 or the connection point between the first coupling electrode 10 and the antenna conductor 12 is an antenna foot point for the pickup of antenna signals of the planar antenna. Can be regarded as. However, the second connector contact 14 of the antenna conductor 12 actually functions as a common antenna foot point 13 for the pickup of antenna signals of both planar and linear antennas. As such, antenna signals of the planar antenna and of the linear antenna become available at the second connector contact 14.

The second connector contact 14 is electrically coupled to the connector conductor 19 parasiticly acting as an antenna. In this exemplary embodiment, the connector conductor 19 is electrically coupled to the second conductor contact 14, but the provision of capacitive coupling is equally possible. The hybrid antenna structure 1 is electrically connected to downstream electronic components, for example to an antenna amplifier, via a connector conductor 19 and a connector 31, the antenna signals being connected to the connector conductor 19. Through the laminated plate member 20 is drawn out. As shown in FIG. 2B, the connector conductor 19 extends from the adhesive layer 21 past the edge 5 of the plate member to the fourth plate member surface 27 (side IV), and then the laminated plate member. It is derived far from 20. The spatial position of the second connector contact 14 is selected so that the connector conductor 19 is as short as possible and the parasitic effect of the connector conductor as an antenna is minimized so as not to use a conductor specifically designed for high frequencies. do. Preferably, the connector conductor 19 is shorter than 100 mm. Thus, the connector conductor 19 can be implemented in this case as, for example, an unshielded standard wire or coil conductor, which standard wire or coil conductor is inexpensive and saves space, It can also be connected using a relatively simple connection method. In this case, for example, the width of the connector conductor 19, which is embodied as flat conductors, is preferably tapered towards the edge 5 of the plate member, thus preventing capacitive coupling with the vehicle body.

In the hybrid antenna structure 1, a transparent, conductive coating 6 can fulfill other functions, depending on the material composition. For example, such a conductive coating can function as a hot-reflective coating for protection from sunlight, temperature control, or thermal insulation, or as a heating layer for electrical heating of the laminated plate member 20. These functions are of secondary importance in the case of the present invention.

The outer plate member 2 also has an opaque colored layer applied on the second plate member surface 25 (side II) and forms a framed peripheral masking strip 9, which is specifically illustrated in the figures. Not shown. The coloring layer is preferably made of an electrically non-conductive black pigmented material which can be baked into the outer plate member 2. On the other hand, the masking strip 9 blocks the visibility of the adhesive strands capable of adhering the laminated plate member 20 into the vehicle body; On the one hand, it functions as a UV protection for the adhesive material used.

The conductive coating 6, which functions as a planar antenna, has two flat regions protruding adjacent the edge 5a of the plate member, in which case it is the second (capacitive) coupling electrode 36, 36 '. Function). In FIG. 1, the two flat protrusions have at least a schematic rectangular shape, in which case the provision of any other shape suitable for the application can also be made. The conductive coating 6 does not have a segmented edge region 15 in flat sections adjacent to the two second coupling electrodes 36, 36 ′. In this case, two second coupling electrodes 36, 36 ′ extend into the other coating-free edge strip 7.

As shown in FIG. 2C, the carrier 4 with the conductive coating 6 is introduced into a position opposite the conductive structure 37 and capacitively coupled to the structure. More precisely: the first flat section 40, 40 ′ of the coating 6, which corresponds to the second coupling electrodes 36, 36 ′ and functions as the first capacitive coupling surface, has a second capacitive coupling surface. Located in a parallel opposite position to the second surface section 41 of the conductive structure 37 which serves as a (coupling counter surface), wherein the two first coupling surfaces are capacitive relative to the second coupling surface. Is coupled to. The conductive structure 37 may be, for example, a body of a vehicle. The conductive structure 37 is in this case fixedly bonded to the fourth plate member surface 27 of the inner plate member 3 by, for example, an adhesive bead 38. Thereafter, the conductive coating 6 is capacitively coupled to the conductive structure 37 by two second coupling electrodes 36, 36 ′. As shown in FIG. 2D, the conductive coating 6 outside the two second coupling electrodes 36, 36 ′ is not disposed in a position opposite the conductive structure 37, and thus the conductive structure 37 ) Is not capacitively coupled.

Now, for example, in a vehicle, various sources of interference, such as clocked electrical devices, for example sensors, cameras, engine control devices, etc., are conductive, functioning as planar antennas due to the large antenna area. It is possible to emit electromagnetic interference signals in the form of free space electromagnetic waves which can be received by the coating 6. In FIG. 1, by way of example, two physical interference sources 39, 39 ′ are projected at the projection site in the area of the coating-free edge strip 7 at the long edge 5a of the plate member at the upper and lower ends. Shown schematically by

Trunk signals of the two interference sources 39, 39 ′ received by the planar antenna are, within the two interference region zone members 42, 42 ′, a signal amplitude that is greater than the extremely large signal amplitude or a definable amplitude value. Has The points of the upper interference area zone member 42 have an extremely short (eg vertical) distance from the upper interference source 39, and the points of the lower interference area zone member 42 ′ are the lower interference sources ( 39 ') and extremely short (e.g., vertical) distance. It will be appreciated that the shapes of the interference zone zone members 42, 42 ′ depend on the shape of each of the interferers 39, 39 ′, and the shapes shown in FIG. 1 will be considered as examples only.

As shown in FIG. 1, the second coupling electrode 36 is disposed adjacent to the first coupling electrode 10 and the upper interference region of the first coupling electrode 10 and the upper interference source 39. It is located between the zone members 42. The second coupling electrode 36 is then in this case a first couple, for example less than 7.5 cm corresponding to one quarter of the minimum wavelength of the interference signals in the frequency range of the local broadcast bands III-V. Geometric distance from the ring electrode 10. The second coupling electrode 36 'is disposed adjacent to the lower interference region zone source 42' of the lower interference source 39 '. The second coupling electrode 36 'has a geometric distance from the lower interference zone zone source 42' in this case, for example, less than 7.5 cm. In addition, the two second coupling electrodes 36, 36 ′, together with the coupling counter surface of the conductive structure 37, have a frequency-selective pass behavior and act as a high pass filter, with two agents The coupling counter surface of the two coupling electrodes 36, 36 ′ and the conductive structure 37 is configured in this case to only allow passage of frequencies in excess of, for example, 170 MHz. Accordingly, two second coupling electrodes 36, 36 ′ act frequency-selectively with respect to local broadcast bands III-V. In this case, it is assumed that the interfering signals of the two interfering sources 39, 39 'are located in the frequency range exceeding 170 MHz. The desired frequency selectivity can be obtained in a simple manner by setting the capacitive properties of the second coupling electrodes 36, 36 ′ capacitively coupled to the conductive structure 37. To this end, the size of the (capacitively active) surfaces of the second coupling electrodes 36, 36 ′ and the conductive structure 37 disposed in opposite positions and the distance between these capacitively active surfaces Just set the size in the proper way.

Accordingly, the interference signals received from the upper interference source 39 (and additionally from the lower interference source 39 ') are planar based on the frequency-selective passing behavior of the upper second coupling electrode 36. It is preferentially extracted from the conductive coating 6 which functions as an antenna. Furthermore, between the first coupling electrode 10 and the upper interference region 42 from the surface section of the conductive coating 6 including the upper second coupling electrode 36 and the upper interference region zone member 42. Based on the physical location, the interference signals of the upper interference source 39 are preferentially extracted from the second coupling electrode 36. On the other hand, based on the physical proximity of the second coupling electrode 36 'to the underlying interference region zone member 42', and also from the lower second coupling electrode 36 ', Based on the frequency-selective passing behavior of the two coupling electrodes 36 ', the interference signals received from the lower interference source 39' are preferentially extracted from the conductive coating 6. The physical proximity of the second coupling electrode 36 'to the lower interference area zone member 42' is such that, upon receiving a signal, the lower second coupling electrode 36 'and the lower interference area zone member 42' Causing a potential difference between the surface sections comprising '), the potential difference being greater than the potential difference between this surface section and the first coupling electrode 10, so that these interfering signals are lower second coupling electrode 36'. Is extracted first.

However, the first coupling electrode 10 can extract antenna signals from flat sections of the conductive coating 6 that are different from the interference region zone members 42, 42 ′ where, upon receipt of the signal, the first couple Potential differences for the ring electrode 10 are shown, which is greater than the potential difference for the two second coupling electrodes 36, 36 ′. Effective signals within the frequency range extracted as interfering signals through the conductive structure 37 (ground) can preferably be received via the antenna conductor 12 functioning as a linear antenna, so that substantially no loss of burnout occurs. Do not. The antenna conductor 12 is not interfered by or interferes with the interference signals of the interfering sources 39 and 39 'only to a negligible extent. As such, the antenna assembly 100 with the hybrid antenna structure 1 differs by an excellent signal to noise ratio.

Various embodiments of an antenna assembly 100 having a hybrid antenna structure 1 are described below with reference to other figures, in which case in each case, the second coupling electrodes for the conductive structure 37 ( 36 and 36 'capacitive coupling are realized.

Reference is made to FIGS. 3A and 3B where a first variant of an antenna assembly 100 having a hybrid antenna structure 1 is shown. In order to avoid unnecessary repetition, only different points are described in comparison with the exemplary embodiment of FIGS. 1, 2A and 2B; See the above for the remainder. According to this variant, as the conductive coating 6 is applied on the third plate member surface 26 (side III) of the inner plate member 3, the carrier 4 to the conductive coating 6 is laminated. It is not provided in the plate member 20. The conductive coating 6 does not extend completely to the edge 5 of the plate member, such that a circumferential coating-free edge strip 7 is retained on all sides of the third plate member surface 26. The width of the circumferential edge strip 7 can vary greatly. Preferably, the width of the edge strip 7 is in the range of 0.2 to 1.5 cm, more preferably in the range of 0.3 to 1.3 cm, particularly preferably in the range of 0.4 to 1.0 cm. The edge strip 7 functions in particular for the electrical insulation of the outwardly conductive coating 6 and for the reduction of capacitive coupling to the surrounding conductive structures. The edge strip 7 can be removed later, for example, by abrasion removal, laser removal, or etching, or by the conductive coating 6 on the third plate member surface 26. By masking the inner plate member 3 prior to application.

An antenna conductor 12 that functions as a linear antenna is applied on the third plate member surface 26 in the region of the coating-free edge strip 7. In the variant shown, the antenna conductor 12 is embodied in the form of a flat conductor path 35, which path is preferably applied by printing of a metal printing paste, for example by screen printing. Thus, the linear antenna and the planar antenna are located on the same surface (side III) of the inner plate member 3. A strip-shaped first coupling electrode 10 extends over the antenna conductor 12 and is electrically connected to it, whereby provision of capacitive coupling is equally possible. The antenna conductor 12 is located outside the region 30 schematically shown in FIG. 3A, where all points can be imaged by orthogonal parallel projection onto the planar antenna, such that the linear antenna is connected to the planar antenna. By no electrical loading. FIG. 3A schematically illustrates a (virtual) boundary surface 32 bounding an area 30, which boundary surface is vertically aligned with respect to the third plate member surface 26 and (edge area 15). At) the coating edge 8 or 8 '. In other words, the linear antenna conductor 12 is located in an area not specifically described, where all points can be imaged by orthogonal parallel projection onto the coating-free edge strip 7 serving as a projection area. . In this way, electrical loading of the linear antenna by the planar antenna is preferably avoided.

4A and 4B show a second variant of the antenna assembly 100 with the hybrid antenna structure 1, only illustrating differences from the first variant of FIGS. 3A and 3B; See the above for the remainder. According to this variant, no laminated plate member 20 is provided, for example only a single plate glass having one individual plate member corresponding to the outer plate member 2 is provided. A conductive coating 6 is applied onto the first plate member surface 24 (side I), and such conductive coating 6 does not fully reach the edge 5 of the plate member, and thus the circumferential coating-free The edge strip 7 is retained on all sides of the first plate member surface 24. Within the region of the coating-free edge strip 7, a linear antenna conductor 12 embodied in the form of a conductor path 35 and functioning as a linear antenna is applied on the first plate member surface 24. As such, the antenna conductor 12 is located outside the region 30 schematically shown in FIG. 4A, where all points can be imaged by orthogonal parallel projection onto the planar antenna. The connector conductor 19 is brought into contact with the second connector contact 14 of the antenna conductor 12 and then led to the same phase of the outer plate member 2 away from the antenna conductor 12.

5A and 5B show a third variant of the antenna assembly 100 with the hybrid antenna structure 1, only illustrating differences from the first exemplary embodiment of FIGS. 1, 2A and 2B; See the above for the remainder. According to this variant, the carrier 4 is provided in the laminated plate member 20, on which the conductive coating 6 is applied. A strip-shaped first coupling electrode 10 is applied onto the fourth surface (side IV) of the inner plate member 3 and is capacitively coupled to the conductive coating 6 which functions as a planar antenna. The antenna conductor 12 functioning as a linear antenna is similarly applied onto the fourth plate member surface 27 of the inner plate member 3, for example by printing such as screen printing, and coupling Although electrically coupled to the electrode, provision of capacitive coupling is equally possible. Thus, the planar antenna and the linear antenna are located on different surfaces of different substrates. An antenna conductor 12 is located outside the area 30, where all points can be imaged by orthogonal parallel projection onto the planar antenna 6, whereby the linear antenna is electrically loaded by the planar antenna. It doesn't work. The connector conductor 19 is in contact with the antenna conductor 12 and is drawn directly away from the laminated plate member 20.

FIG. 6 shows a fourth variant of the antenna assembly 100 with the hybrid antenna structure 1, in which only differences from the third variant of FIGS. 5A and 5B are described; See the above for the remainder. According to this variant, a linear antenna conductor 12 configured as a flat conductor path 35 is applied on the third plate member surface 26 of the inner plate member 3. A second connecting conductor 34 is applied onto the antenna conductor 12 within the antenna foot point and the short edge of the plate member to the fourth plate member surface 27 (side IV) of the inner plate member 3 ( Extend beyond 5b). In the variant described, the second connecting conductor 34 is electrically coupled to the antenna conductor 12 and the provision of capacitive coupling is equally possible. The second connecting conductor 34 may be made of the same material as the coupling electrode 10, for example. The connector conductor 19 is in contact with the second connecting conductor 34 on the fourth plate member surface 27 and is drawn away from the laminated plate member 20. The width (dimensions perpendicular to the direction of extension) of the second connecting conductor 34, configured as a strip-shaped flat conductor, is preferably tapered towards the short edge 5b of the plate member, so that the conductive coating 6 Capacitive coupling between the vehicle and the conductive vehicle body can be prevented.

7, 8a and 8b show a second exemplary embodiment of an antenna assembly with a hybrid antenna structure 1 according to the invention, wherein only differences from the first exemplary embodiment of FIGS. 1, 2a and 2b To explain; See the above for the remainder. According to this embodiment, the laminated plate member 20 has a carrier 4 embedded in the adhesive layer 21 and a transparent conductive coating 6 applied on the second carrier surface 23. The conductive coating 6 is applied on the entire surface of the second carrier surface 23 without implementing the fragmented edge region 15; The provision of fragmented edge regions is likewise possible.

Although the first coupling electrode 10 is in contact with and electrically coupled to the conductive coating 6, the provision of capacitive coupling is equally possible. The first coupling electrode 10 extends beyond the long edge 5a of the upper plate member to the fourth plate member surface 27 (side IV) of the inner plate member 3. The linear antenna conductor 12 is a conductor on the fourth plate member surface 27 of the inner plate member 3, similar to the third variant of the first exemplary embodiment described in connection with FIGS. 5A and 5B. It is applied as a path 35. At its other end, the first coupling electrode 10 is in contact with and electrically coupled to the antenna conductor 12, but the provision of capacitive coupling is equally possible. An antenna conductor 12 is located outside the area 30, where all points can be imaged by orthogonal parallel projection onto the planar antenna, such that the linear antenna is not electrically loaded by the planar antenna. The connector conductor 19 is in contact with the antenna conductor 12 and is drawn directly away from the laminated plate member 20.

FIG. 9 shows a variant having only differences from the exemplary second embodiment described in FIGS. 7, 8A and 8B, to avoid repetition. According to this embodiment, the first coupling electrode 10 is implemented only in the region of the conductive coating 6, is in direct contact with the region, and is thus electrically coupled to the conductive coating 6. It is equally possible to provide red couplings. The first connecting conductor 33, at one of its ends, is in direct contact with the first coupling electrode 10 and electrically coupled to the conductive coating 6, but providing the same capacitive coupling. It is possible to. The first connecting conductor 33 extends beyond the long edge 5a of the upper part of the plate member to the fourth plate member surface 27 (side IV) of the inner plate member 3 and at the other end of the conductive member. In contact with the antenna conductor 12 implemented as a sieve path. The first connecting conductor 33 is in direct contact with the antenna conductor 12 and electrically coupled, for example by a soldering contact, but the provision of capacitive coupling is equally possible. The first connecting conductor 33 can be made of the same material as the first coupling electrode 10, for example, so that the first coupling electrode 10 and the first connecting conductor 33 are made. Together can be regarded as a two-part coupling electrode. The width (dimensions perpendicular to the extension direction) of the first connecting conductor 33 configured as a strip-shaped flat conductor is preferably tapered towards the long edge 5a of the plate member, and thus the conductive coating 6 ) And the capacitive coupling between the bodywork is prevented.

The present invention enables the use of an antenna assembly having a hybrid antenna structure that enables bandwidth optimized reception of electromagnetic waves, wherein through planar and linear antenna combinations, satisfactory reception performance is achieved over the entire frequency range of bands IV. Can be. The antenna assembly has a good signal-to-noise ratio by the possibility that interfering signals of external interferers received by the planar antenna as free space waves can be extracted through ground coupled capacitively to the planar antenna.

One; Antenna structures
2; Outer plate member
3; Inner plate member
4; carrier
5; Edge of plate member
5a; Long edge of plate member
5b; Short edge of plate member
6; coating
7; Edge strip
8, 8 '; Coated edge
9; Masking strip
10; First coupling electrode
11; First connector contacts
12; Antenna conductor
13; Antenna foot point
14; 2nd connector contact
15; Edge area
16; snippet
17; Insulation area
18; wire
19; Connector conductor
20; Laminated Plate Member
21; Adhesive layer
22; First carrier surface
23; Second carrier surface
24; First plate member surface
25; Second plate member surface
26; Third plate member surface
27; 4th plate member surface
28; Edge Zone
29; Carrier edge
30; domain
31; connector
32; Boundary surface
33; First connecting conductor
34; Second connecting conductor
35; Conductor path
36, 36 '; Second coupling electrode
37; Conductive structure
38; Adhesive beads
39, 39 '; Interference
40, 40 '; First flat section
41; 2nd flat section
42, 42 '; Interference zone
100; Antenna assembly

Claims (13)

As antenna assembly 100:
At least one electrically insulating, in particular transparent substrate 2-4;
At least one conductive coating, particularly transparent, which covers at least the section 22-27 of the substrate in a section-wise manner and serves as a planar antenna for receiving electromagnetic waves at least in a section-wise manner;
At least one first coupling electrode (10) electrically coupled to the conductive coating (6) to extract an effective signal from the planar antenna;
At least one interference source (39, 39 ') arranged such that interference signals can be received by the planar antenna;
A conductive structure 37 serving as a ground, for example a metal body or a metal window frame; And
At least one second coupling electrode 36, 36 ′ electrically coupled to the conductive coating 6 to extract interference signals of the at least one interference source 39, 39 ′ from the planar antenna. Including,
The at least one second coupling electrode 36, 36 ′ has a first coupling surface 40, 40 ′, and the conductive structure 37 is capacitive to the first coupling surface 43. Having a second coupling surface 41 coupled, the first coupling surface 40, 40 ′ and the second coupling surface 41 correspond to interference signals extracted from the planar antenna. An antenna assembly (100) configured to selectively allow passage of a frequency range. The method of claim 1,
The at least one second coupling electrode (36, 36 ') is embodied in the form of a projecting edge section of the conductive coating (6). The method according to claim 1 or 2,
The at least one second coupling electrode 36, 36 ′ is close to the first coupling electrode 10, in particular the first coupling electrode 10 which is less than one quarter of the minimum wavelength of the interference signal. An antenna assembly (100) disposed at a distance from the antenna assembly. 4. The method according to any one of claims 1 to 3,
The at least one second coupling electrode 36, 36 ′ is an interference area zone member of the conductive coating 6 having points at a distance as short as possible from the at least one interference source 39, 39 ′. (42, 42 ') and an antenna assembly (100) disposed between the first coupling electrode (10). 5. The method according to any one of claims 1 to 4,
Interference region zone source of the conductive coating 6 having points at a distance as short as possible from the at least one second coupling electrode 36, 36 ′ and the at least one interference source 39, 39 ′ ( 42, 42 '), wherein the geometrical distance between the first coupling electrode (10) and the interference area zone member (42, 42') is shorter than the geometrical distance. The method according to claim 4 or 5,
And the at least one second coupling electrode (36, 36 ') is distanced from the interference region zone member (42, 42') that is less than one quarter of the minimum wavelength of the interference signal. 7. The method according to any one of claims 1 to 6,
The capacitively coupled coupling surfaces 40, 40 ′, 41 of the conductive structure 37 and the at least one second coupling electrode 36, 36 ′ have a frequency range in excess of 170 MHz. An antenna assembly (100) configured to selectively allow passage. 8. The method according to any one of claims 1 to 7,
The first coupling electrode 10 is electrically coupled to an unshielded linear antenna conductor 12 functioning as a linear antenna for receiving electromagnetic waves, the linear antenna conductor functioning as a projection area. Located outside of the area 30 that can be projected by orthogonal parallel projection onto it, so that one antenna foot point of the linear antenna is a common antenna foot point of the linear antenna and the planar antenna 13), antenna assembly (100). As the antenna structure 1:
At least one electrically insulating, in particular transparent substrate 2-4;
At least one conductive coating, particularly transparent, which covers at least the section 22-27 of the substrate in a section-wise manner and serves as a planar antenna for receiving electromagnetic waves at least in a section-wise manner;
At least one first coupling electrode (10) electrically coupled to the conductive coating (6) to extract an effective signal from the planar antenna;
At least one second coupling electrode 36, 36 ′ electrically coupled to the conductive coating 6 to extract interference signals of at least one interference source 39, 39 ′ from the planar antenna. and,
The at least one second coupling electrode 36, 36 ′ is a first coupling surface 40 configured to be capacitively coupled to a second coupling surface 41 of the conductive structure 37 acting as electrical ground. , 40 ', the first coupling surface 40, 40', together with the second coupling surface 41, of a frequency range corresponding to the interference signals coupled out from the planar antenna. Antenna structure 1, configured to selectively allow passage. 10. The method of claim 9,
The at least one second coupling electrode (36, 36 ') is configured in the form of a projecting edge section of the conductive coating (6). Use of the antenna structure 1 according to claim 9 or 10,
In land, air, or sea vehicles, especially in vehicles, for example as windshields, rear windows, side windows, and / or glass ceilings, as well as embedded parts in furniture, devices, and buildings, and Use of the antenna structure 1, used as a functional individual piece. As a method of operation of the antenna assembly 100:
Receiving valid signals by means of a planar antenna implemented in the form of a particularly transparent conductive coating 6 applied to at least one electrically insulating, in particular transparent substrate 2-4;
Extracting valid signals from a planar antenna by a first coupling electrode (10) electrically coupled to the coating (6); And
Interfering signals of at least one interference source 39, 39 ′ received by the planar antenna by a second coupling electrode 36, 36 ′ electrically coupled to the coating 6. Optionally extracting from
The second coupling electrodes 36, 36 ′ are capacitively coupled to a conductive structure 37, for example a metal body or a metal window frame, which acts as a ground, and the second coupling electrodes 36, 36 ′ has a first coupling surface 40, 40 ′, and the conductive structure 37 has a second coupling surface (capacitively coupled to the first coupling surface 40, 40 ′). 41), a method of operating an antenna assembly (100). The method of claim 12,
Interference signals received by the planar antenna are extracted from the planar antenna via at least one second coupling electrode 36, 36 ′ configured in the form of a projecting edge section of the conductive coating 6. ) Operation method.

Images